2025-03-07 ペンシルベニア州立大学
<関連情報>
- https://www.psu.edu/news/research/story/nanodot-control-could-fine-tune-light-sharper-displays-quantum-computing
- https://pubs.acs.org/doi/10.1021/acsphotonics.4c01739
二次元の量子閉じ込めルミネッセンス Quantum Confined Luminescence in Two Dimensions
Saiphaneendra Bachu,Fatimah Habis,Benjamin Huet,Steffi Y. Woo,Leixin Miao,Danielle Reifsnyder Hickey,Gwangwoo Kim,Nicholas Trainor,Kenji Watanabe,Takashi Taniguchi,Deep Jariwala,Joan M. Redwing,Yuanxi Wang,Mathieu Kociak,Luiz H. G. Tizei,and Nasim Alem
ACS Photonics Published:December 26, 2024
Abstract
Achieving localized light emission from monolayer two-dimensional (2D) transition metal dichalcogenides (TMDs) embedded in the matrix of another TMD has been theoretically proposed but not experimentally proven. In this study, we used cathodoluminescence performed in a scanning transmission electron microscope to unambiguously resolve localized light emission from 2D monolayer MoSe2 nanodots of varying sizes embedded in a monolayer WSe2 matrix. We observed that the light emission strongly depends on the nanodot size, wherein the emission is dominated by MoSe2 excitons in dots larger than 85 nm and by MoSe2/WSe2 interface excitons below 50 nm. Interestingly, at extremely small dot sizes (<10 nm), the electron energy levels in the nanodot become quantized, as demonstrated by a striking blue-shift in interface exciton emission, thus inducing quantum confined luminescence. These results establish controllable light emission from spatially confined 2D nanodots, which holds potential to be generalized to other 2D systems toward future nanophotonic applications.
